On this page:
object%
class*
class
this
this%
inspect
init
init-field
field
inherit-field
init-rest
public
pubment
public-final
override
overment
override-final
augment
augride
augment-final
private
abstract
inherit
inherit/  super
inherit/  inner
rename-super
rename-inner
public*
pubment*
public-final*
override*
overment*
override-final*
augment*
augride*
augment-final*
private*
define/  public
define/  pubment
define/  public-final
define/  override
define/  overment
define/  override-final
define/  augment
define/  augride
define/  augment-final
define/  private
class/  derived
5.2.1 Initialization Variables
5.2.2 Fields
5.2.3 Methods
5.2.3.1 Method Definitions
super
inner
5.2.3.2 Inherited and Superclass Methods
5.2.3.3 Internal and External Names
define-local-member-name
define-member-name
member-name-key
generate-member-key
member-name-key?
member-name-key=?
member-name-key-hash-code

5.2 Creating Classes

+Classes and Objects in The Racket Guide introduces classes and objects.

value

object% : class?

A built-in class that has no methods fields, implements only its own interface (class->interface object%), and is transparent (i.e,. its inspector is #f, so all immediate instances are equal?). All other classes are derived from object%.

syntax

(class* superclass-expr (interface-expr ...)
  class-clause
  ...)
 
class-clause = (inspect inspector-expr)
  | (init init-decl ...)
  | (init-field init-decl ...)
  | (field field-decl ...)
  | (inherit-field maybe-renamed ...)
  | (init-rest id)
  | (init-rest)
  | (public maybe-renamed ...)
  | (pubment maybe-renamed ...)
  | (public-final maybe-renamed ...)
  | (override maybe-renamed ...)
  | (overment maybe-renamed ...)
  | (override-final maybe-renamed ...)
  | (augment maybe-renamed ...)
  | (augride maybe-renamed ...)
  | (augment-final maybe-renamed ...)
  | (private id ...)
  | (abstract id ...)
  | (inherit maybe-renamed ...)
  | (inherit/super maybe-renamed ...)
  | (inherit/inner maybe-renamed ...)
  | (rename-super renamed ...)
  | (rename-inner renamed ...)
  | method-definition
  | definition
  | expr
  | (begin class-clause ...)
     
init-decl = id
  | (renamed)
  | (maybe-renamed default-value-expr)
     
field-decl = (maybe-renamed default-value-expr)
     
maybe-renamed = id
  | renamed
     
renamed = (internal-id external-id)
     
method-definition = (define-values (id) method-procedure)
     
method-procedure = (lambda kw-formals expr ...+)
  | (case-lambda (formals expr ...+) ...)
  | (#%plain-lambda formals expr ...+)
  | 
(let-values ([(id) method-procedure] ...)
  method-procedure)
  | 
(letrec-values ([(id) method-procedure] ...)
  method-procedure)
  | 
(let-values ([(id) method-procedure] ...+)
  id)
  | 
(letrec-values ([(id) method-procedure] ...+)
  id)
Produces a class value.

The superclass-expr expression is evaluated when the class* expression is evaluated. The result must be a class value (possibly object%), otherwise the exn:fail:object exception is raised. The result of the superclass-expr expression is the new class’s superclass.

The interface-expr expressions are also evaluated when the class* expression is evaluated, after superclass-expr is evaluated. The result of each interface-expr must be an interface value, otherwise the exn:fail:object exception is raised. The interfaces returned by the interface-exprs are all implemented by the class. For each identifier in each interface, the class (or one of its ancestors) must declare a public method with the same name, otherwise the exn:fail:object exception is raised. The class’s superclass must satisfy the implementation requirement of each interface, otherwise the exn:fail:object exception is raised.

An inspect class-clause selects an inspector (see Structure Inspectors) for the class extension. The inspector-expr must evaluate to an inspector or #f when the class* form is evaluated. Just as for structure types, an inspector controls access to the class’s fields, including private fields, and also affects comparisons using equal?. If no inspect clause is provided, access to the class is controlled by the parent of the current inspector (see Structure Inspectors). A syntax error is reported if more than one inspect clause is specified.

The other class-clauses define initialization arguments, public and private fields, and public and private methods. For each id or maybe-renamed in a public, override, augment, pubment, overment, augride, public-final, override-final, augment-final, or private clause, there must be one method-definition. All other definition class-clauses create private fields. All remaining exprs are initialization expressions to be evaluated when the class is instantiated (see Creating Objects).

The result of a class* expression is a new class, derived from the specified superclass and implementing the specified interfaces. Instances of the class are created with the instantiate form or make-object procedure, as described in Creating Objects.

Each class-clause is (partially) macro-expanded to reveal its shapes. If a class-clause is a begin expression, its sub-expressions are lifted out of the begin and treated as class-clauses, in the same way that begin is flattened for top-level and embedded definitions.

Within a class* form for instances of the new class, this is bound to the object itself; this% is bound to the class of the object; super-instantiate, super-make-object, and super-new are bound to forms to initialize fields in the superclass (see Creating Objects); super is available for calling superclass methods (see Method Definitions); and inner is available for calling subclass augmentations of methods (see Method Definitions).

syntax

(class superclass-expr class-clause ...)

Like class*, but omits the interface-exprs, for the case that none are needed.

Example:

(define book-class%
  (class object%
    (field (pages 5))
    (define/public (letters)
      (* pages 500))
    (super-new)))

syntax

this

Within a class* form, this refers to the current object (i.e., the object being initialized or whose method was called). Use outside the body of a class* form is a syntax error.

Examples:

(define (describe obj)
  (printf "Hello ~a\n" obj))
(define table%
  (class object%
    (define/public (describe-self)
      (describe this))
    (super-new)))
> (send (new table%) describe-self)

Hello #(struct:object:table% ...)

syntax

this%

Within a class* form, this% refers to the class of the current object (i.e., the object being initialized or whose method was called). Use outside the body of a class* form is a syntax error.

Examples:

(define account%
  (class object%
    (super-new)
    (init-field balance)
    (define/public (add n)
      (new this% [balance (+ n balance)]))))
(define savings%
  (class account%
    (super-new)
    (inherit-field balance)
    (define interest 0.04)
    (define/public (add-interest)
      (send this add (* interest balance)))))
> (let* ([acct (new savings% [balance 500])]
         [acct (send acct add 500)]
         [acct (send acct add-interest)])
    (printf "Current balance: ~a\n" (get-field balance acct)))

Current balance: 1040.0

syntax

(inspect inspector-expr)

See class*; use outside the body of a class* form is a syntax error.

syntax

(init init-decl ...)

See class* and Initialization Variables; use outside the body of a class* form is a syntax error.

Example:

> (class object%
    (super-new)
    (init turnip
          [(internal-potato potato)]
          [carrot 'good]
          [(internal-rutabaga rutabaga) 'okay]))

#<class:eval:10:0>

syntax

(init-field init-decl ...)

See class*, Initialization Variables, and Fields; use outside the body of a class* form is a syntax error.

Example:

> (class object%
    (super-new)
    (init-field turkey
                [(internal-ostrich ostrich)]
                [chicken 7]
                [(internal-emu emu) 13]))

#<class:eval:11:0>

syntax

(field field-decl ...)

See class* and Fields; use outside the body of a class* form is a syntax error.

Example:

> (class object%
    (super-new)
    (field [minestrone 'ready]
           [(internal-coq-au-vin coq-au-vin) 'stewing]))

#<class:eval:12:0>

syntax

(inherit-field maybe-renamed ...)

See class* and Fields; use outside the body of a class* form is a syntax error.

Examples:

(define cookbook%
  (class object%
    (super-new)
    (field [recipes '(caldo-verde oyakodon eggs-benedict)]
           [pages 389])))
> (class cookbook%
    (super-new)
    (inherit-field recipes
                   [internal-pages pages]))

#<class:eval:14:0>

syntax

(init-rest id)

(init-rest)
See class* and Initialization Variables; use outside the body of a class* form is a syntax error.

Examples:

(define fruit-basket%
  (class object%
    (super-new)
    (init-rest fruits)
    (displayln fruits)))
> (make-object fruit-basket% 'kiwi 'lychee 'melon)

(kiwi lychee melon)

(object:fruit-basket% ...)

syntax

(public maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define jumper%
  (class object%
    (super-new)
    (define (skip) 'skip)
    (define (hop) 'hop)
    (public skip [hop jump])))
> (send (new jumper%) skip)

'skip

> (send (new jumper%) jump)

'hop

syntax

(pubment maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define runner%
  (class object%
    (super-new)
    (define (run) 'run)
    (define (trot) 'trot)
    (pubment run [trot jog])))
> (send (new runner%) run)

'run

> (send (new runner%) jog)

'trot

syntax

(public-final maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define point%
  (class object%
    (super-new)
    (init-field [x 0] [y 0])
    (define (get-x) x)
    (define (do-get-y) y)
    (public-final get-x [do-get-y get-y])))
> (send (new point% [x 1] [y 3]) get-y)

3

> (class point%
    (super-new)
    (define (get-x) 3.14)
    (override get-x))

class*: cannot override or augment final method

  method name: get-x

  class name: eval:25:0

syntax

(override maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define sheep%
  (class object%
    (super-new)
    (define/public (bleat)
      (displayln "baaaaaaaaah"))))
(define confused-sheep%
  (class sheep%
    (super-new)
    (define (bleat)
      (super bleat)
      (displayln "???"))
    (override bleat)))
> (send (new sheep%) bleat)

baaaaaaaaah

> (send (new confused-sheep%) bleat)

baaaaaaaaah

???

syntax

(overment maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define turkey%
  (class object%
    (super-new)
    (define/public (gobble)
      (displayln "gobble gobble"))))
(define extra-turkey%
  (class turkey%
    (super-new)
    (define (gobble)
      (super gobble)
      (displayln "gobble gobble gobble")
      (inner (void) gobble))
    (overment gobble)))
(define cyborg-turkey%
  (class extra-turkey%
    (super-new)
    (define/augment (gobble)
      (displayln "110011111011111100010110001011011001100101"))))
> (send (new extra-turkey%) gobble)

gobble gobble

gobble gobble gobble

> (send (new cyborg-turkey%) gobble)

gobble gobble

gobble gobble gobble

110011111011111100010110001011011001100101

syntax

(override-final maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define meeper%
  (class object%
    (super-new)
    (define/public (meep)
      (displayln "meep"))))
(define final-meeper%
  (class meeper%
    (super-new)
    (define (meep)
      (super meep)
      (displayln "This meeping ends with me"))
    (override-final meep)))
> (send (new meeper%) meep)

meep

> (send (new final-meeper%) meep)

meep

This meeping ends with me

syntax

(augment maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define buzzer%
  (class object%
    (super-new)
    (define/pubment (buzz)
      (displayln "bzzzt")
      (inner (void) buzz))))
(define loud-buzzer%
  (class buzzer%
    (super-new)
    (define (buzz)
      (displayln "BZZZZZZZZZT"))
    (augment buzz)))
> (send (new buzzer%) buzz)

bzzzt

> (send (new loud-buzzer%) buzz)

bzzzt

BZZZZZZZZZT

syntax

(augride maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

syntax

(augment-final maybe-renamed ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

syntax

(private id ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define light%
  (class object%
    (super-new)
    (define on? #t)
    (define (toggle) (set! on? (not on?)))
    (private toggle)
    (define (flick) (toggle))
    (public flick)))
> (send (new light%) toggle)

send: no such method

  method name: toggle

  class name: light%

> (send (new light%) flick)

syntax

(abstract id ...)

See class* and Method Definitions; use outside the body of a class* form is a syntax error.

Examples:

(define train%
  (class object%
    (super-new)
    (abstract get-speed)
    (init-field [position 0])
    (define/public (move)
      (new this% [position (+ position (get-speed))]))))
(define acela%
  (class train%
    (super-new)
    (define/override (get-speed) 241)))
(define talgo-350%
  (class train%
    (super-new)
    (define/override (get-speed) 330)))
> (new train%)

instantiate: cannot instantiate class with abstract methods

  class: #<class:train%>

  abstract methods:

   get-speed

> (send (new acela%) move)

(object:acela% ...)

syntax

(inherit maybe-renamed ...)

See class* and Inherited and Superclass Methods; use outside the body of a class* form is a syntax error.

Examples:

(define alarm%
  (class object%
    (super-new)
    (define/public (alarm)
      (displayln "beeeeeeeep"))))
(define car-alarm%
  (class alarm%
    (super-new)
    (init-field proximity)
    (inherit alarm)
    (when (< proximity 10)
      (alarm))))
> (new car-alarm% [proximity 5])

beeeeeeeep

(object:car-alarm% ...)

syntax

(inherit/super maybe-renamed ...)

See class* and Inherited and Superclass Methods; use outside the body of a class* form is a syntax error.

syntax

(inherit/inner maybe-renamed ...)

See class* and Inherited and Superclass Methods; use outside the body of a class* form is a syntax error.

syntax

(rename-super renamed ...)

See class* and Inherited and Superclass Methods; use outside the body of a class* form is a syntax error.

syntax

(rename-inner renamed ...)

See class* and Inherited and Superclass Methods; use outside the body of a class* form is a syntax error.

syntax

(public* (id expr) ...)

Shorthand for (begin (public id) ... (define id expr) ...).

syntax

(pubment* (id expr) ...)

Shorthand for (begin (pubment id) ... (define id expr) ...).

syntax

(public-final* (id expr) ...)

Shorthand for (begin (public-final id) ... (define id expr) ...).

syntax

(override* (id expr) ...)

Shorthand for (begin (override id) ... (define id expr) ...).

syntax

(overment* (id expr) ...)

Shorthand for (begin (overment id) ... (define id expr) ...).

syntax

(override-final* (id expr) ...)

Shorthand for (begin (override-final id) ... (define id expr) ...).

syntax

(augment* (id expr) ...)

Shorthand for (begin (augment id) ... (define id expr) ...).

syntax

(augride* (id expr) ...)

Shorthand for (begin (augride id) ... (define id expr) ...).

syntax

(augment-final* (id expr) ...)

Shorthand for (begin (augment-final id) ... (define id expr) ...).

syntax

(private* (id expr) ...)

Shorthand for (begin (private id) ... (define id expr) ...).

syntax

(define/public id expr)

(define/public (id . formals) body ...+)
Shorthand for (begin (public id) (define id expr)) or (begin (public id) (define (id . formals) body ...+))

syntax

(define/pubment id expr)

(define/pubment (id . formals) body ...+)
Shorthand for (begin (pubment id) (define id expr)) or (begin (pubment id) (define (id . formals) body ...+))

syntax

(define/public-final id expr)

(define/public-final (id . formals) body ...+)
Shorthand for (begin (public-final id) (define id expr)) or (begin (public-final id) (define (id . formals) body ...+))

syntax

(define/override id expr)

(define/override (id . formals) body ...+)
Shorthand for (begin (override id) (define id expr)) or (begin (override id) (define (id . formals) body ...+))

syntax

(define/overment id expr)

(define/overment (id . formals) body ...+)
Shorthand for (begin (overment id) (define id expr)) or (begin (overment id) (define (id . formals) body ...+))

syntax

(define/override-final id expr)

(define/override-final (id . formals) body ...+)
Shorthand for (begin (override-final id) (define id expr)) or (begin (override-final id) (define (id . formals) body ...+))

syntax

(define/augment id expr)

(define/augment (id . formals) body ...+)
Shorthand for (begin (augment id) (define id expr)) or (begin (augment id) (define (id . formals) body ...+))

syntax

(define/augride id expr)

(define/augride (id . formals) body ...+)
Shorthand for (begin (augride id) (define id expr)) or (begin (augride id) (define (id . formals) body ...+))

syntax

(define/augment-final id expr)

(define/augment-final (id . formals) body ...+)
Shorthand for (begin (augment-final id) (define id expr)) or (begin (augment-final id) (define (id . formals) body ...+))

syntax

(define/private id expr)

(define/private (id . formals) body ...+)
Shorthand for (begin (private id) (define id expr)) or (begin (private id) (define (id . formals) body ...+))

syntax

(class/derived original-datum
  (name-id super-expr (interface-expr ...) deserialize-id-expr)
  class-clause
  ...)
Like class*, but includes a sub-expression to be used as the source for all syntax errors within the class definition. For example, define-serializable-class expands to class/derived so that errors in the body of the class are reported in terms of define-serializable-class instead of class.

The original-datum is the original expression to use for reporting errors.

The name-id is used to name the resulting class; if it is #f, the class name is inferred.

The super-expr, interface-exprs, and class-clauses are as for class*.

If the deserialize-id-expr is not literally #f, then a serializable class is generated, and the result is two values instead of one: the class and a deserialize-info structure produced by make-deserialize-info. The deserialize-id-expr should produce a value suitable as the second argument to make-serialize-info, and it should refer to an export whose value is the deserialize-info structure.

Future optional forms may be added to the sequence that currently ends with deserialize-id-expr.

5.2.1 Initialization Variables

A class’s initialization variables, declared with init, init-field, and init-rest, are instantiated for each object of a class. Initialization variables can be used in the initial value expressions of fields, default value expressions for initialization arguments, and in initialization expressions. Only initialization variables declared with init-field can be accessed from methods; accessing any other initialization variable from a method is a syntax error.

The values bound to initialization variables are

If an initialization argument is not provided for an initialization variable that has an associated default-value-expr, then the default-value-expr expression is evaluated to obtain a value for the variable. A default-value-expr is only evaluated when an argument is not provided for its variable. The environment of default-value-expr includes all of the initialization variables, all of the fields, and all of the methods of the class. If multiple default-value-exprs are evaluated, they are evaluated from left to right. Object creation and field initialization are described in detail in Creating Objects.

If an initialization variable has no default-value-expr, then the object creation or superclass initialization call must supply an argument for the variable, otherwise the exn:fail:object exception is raised.

Initialization arguments can be provided by name or by position. The external name of an initialization variable can be used with instantiate or with the superclass initialization form. Those forms also accept by-position arguments. The make-object procedure and the superclass initialization procedure accept only by-position arguments.

Arguments provided by position are converted into by-name arguments using the order of init and init-field clauses and the order of variables within each clause. When an instantiate form provides both by-position and by-name arguments, the converted arguments are placed before by-name arguments. (The order can be significant; see also Creating Objects.)

Unless a class contains an init-rest clause, when the number of by-position arguments exceeds the number of declared initialization variables, the order of variables in the superclass (and so on, up the superclass chain) determines the by-name conversion.

If a class expression contains an init-rest clause, there must be only one, and it must be last. If it declares a variable, then the variable receives extra by-position initialization arguments as a list (similar to a dotted “rest argument” in a procedure). An init-rest variable can receive by-position initialization arguments that are left over from a by-name conversion for a derived class. When a derived class’s superclass initialization provides even more by-position arguments, they are prefixed onto the by-position arguments accumulated so far.

If too few or too many by-position initialization arguments are provided to an object creation or superclass initialization, then the exn:fail:object exception is raised. Similarly, if extra by-position arguments are provided to a class with an init-rest clause, the exn:fail:object exception is raised.

Unused (by-name) arguments are to be propagated to the superclass, as described in Creating Objects. Multiple initialization arguments can use the same name if the class derivation contains multiple declarations (in different classes) of initialization variables with the name. See Creating Objects for further details.

See also Internal and External Names for information about internal and external names.

5.2.2 Fields

Each field, init-field, and non-method define-values clause in a class declares one or more new fields for the class. Fields declared with field or init-field are public. Public fields can be accessed and mutated by subclasses using inherit-field. Public fields are also accessible outside the class via class-field-accessor and mutable via class-field-mutator (see Field and Method Access). Fields declared with define-values are accessible only within the class.

A field declared with init-field is both a public field and an initialization variable. See Initialization Variables for information about initialization variables.

An inherit-field declaration makes a public field defined by a superclass directly accessible in the class expression. If the indicated field is not defined in the superclass, the exn:fail:object exception is raised when the class expression is evaluated. Every field in a superclass is present in a derived class, even if it is not declared with inherit-field in the derived class. The inherit-field clause does not control inheritance, but merely controls lexical scope within a class expression.

When an object is first created, all of its fields have the #<undefined> value (see Void and Undefined). The fields of a class are initialized at the same time that the class’s initialization expressions are evaluated; see Creating Objects for more information.

See also Internal and External Names for information about internal and external names.

5.2.3 Methods
5.2.3.1 Method Definitions

Each public, override, augment, pubment, overment, augride, public-final, override-final, augment-final, and private clause in a class declares one or more method names. Each method name must have a corresponding method-definition. The order of public, etc., clauses and their corresponding definitions (among themselves, and with respect to other clauses in the class) does not matter.

As shown in the grammar for class*, a method definition is syntactically restricted to certain procedure forms, as defined by the grammar for method-procedure; in the last two forms of method-procedure, the body id must be one of the ids bound by let-values or letrec-values. A method-procedure expression is not evaluated directly. Instead, for each method, a class-specific method procedure is created; it takes an initial object argument, in addition to the arguments the procedure would accept if the method-procedure expression were evaluated directly. The body of the procedure is transformed to access methods and fields through the object argument.

A method declared with public, pubment, or public-final introduces a new method into a class. The method must not be present already in the superclass, otherwise the exn:fail:object exception is raised when the class expression is evaluated. A method declared with public can be overridden in a subclass that uses override, overment, or override-final. A method declared with pubment can be augmented in a subclass that uses augment, augride, or augment-final. A method declared with public-final cannot be overridden or augmented in a subclass.

A method declared with override, overment, or override-final overrides a definition already present in the superclass. If the method is not already present, the exn:fail:object exception is raised when the class expression is evaluated. A method declared with override can be overridden again in a subclass that uses override, overment, or override-final. A method declared with overment can be augmented in a subclass that uses augment, augride, or augment-final. A method declared with override-final cannot be overridden further or augmented in a subclass.

A method declared with augment, augride, or augment-final augments a definition already present in the superclass. If the method is not already present, the exn:fail:object exception is raised when the class expression is evaluated. A method declared with augment can be augmented further in a subclass that uses augment, augride, or augment-final. A method declared with augride can be overridden in a subclass that uses override, overment, or override-final. (Such an override merely replaces the augmentation, not the method that is augmented.) A method declared with augment-final cannot be overridden or augmented further in a subclass.

A method declared with private is not accessible outside the class expression, cannot be overridden, and never overrides a method in the superclass.

When a method is declared with override, overment, or override-final, then the superclass implementation of the method can be called using super form.

When a method is declared with pubment, augment, or overment, then a subclass augmenting method can be called using the inner form. The only difference between public-final and pubment without a corresponding inner is that public-final prevents the declaration of augmenting methods that would be ignored.

A method declared with abstract must be declared without an implementation. Subclasses may implement abstract methods via the override, overment, or override-final forms. Any class that contains or inherits any abstract methods is considered abstract and cannot be instantiated.

syntax

(super id arg ...)

(super id arg ... . arg-list-expr)
Always accesses the superclass method, independent of whether the method is overridden again in subclasses. Using the super form outside of class* is a syntax error. Each arg is as for #%app: either arg-expr or keyword arg-expr.

The second form is analogous to using apply with a procedure; the arg-list-expr must not be a parenthesized expression.

syntax

(inner default-expr id arg ...)

(inner default-expr id arg ... . arg-list-expr)
If the object’s class does not supply an augmenting method, then default-expr is evaluated, and the arg expressions are not evaluated. Otherwise, the augmenting method is called with the arg results as arguments, and default-expr is not evaluated. If no inner call is evaluated for a particular method, then augmenting methods supplied by subclasses are never used. Using the inner form outside of class* is an syntax error.

The second form is analogous to using apply with a procedure; the arg-list-expr must not be a parenthesized expression.

5.2.3.2 Inherited and Superclass Methods

Each inherit, inherit/super, inherit/inner, rename-super, and rename-inner clause declares one or more methods that are defined in the class, but must be present in the superclass. The rename-super and rename-inner declarations are rarely used, since inherit/super and inherit/inner provide the same access. Also, superclass and augmenting methods are typically accessed through super and inner in a class that also declares the methods, instead of through inherit/super, inherit/inner, rename-super, or rename-inner.

Method names declared with inherit, inherit/super, or inherit/inner access overriding declarations, if any, at run time. Method names declared with inherit/super can also be used with the super form to access the superclass implementation, and method names declared with inherit/inner can also be used with the inner form to access an augmenting method, if any.

Method names declared with rename-super always access the superclass’s implementation at run-time. Methods declared with rename-inner access a subclass’s augmenting method, if any, and must be called with the form

(id (lambda () default-expr) arg ...)

so that a default-expr is available to evaluate when no augmenting method is available. In such a form, lambda is a literal identifier to separate the default-expr from the arg. When an augmenting method is available, it receives the results of the arg expressions as arguments.

Methods that are present in the superclass but not declared with inherit, inherit/super, or inherit/inner or rename-super are not directly accessible in the class (though they can be called with send). Every public method in a superclass is present in a derived class, even if it is not declared with inherit in the derived class; the inherit clause does not control inheritance, but merely controls lexical scope within a class expression.

If a method declared with inherit, inherit/super, inherit/inner, rename-super, or rename-inner is not present in the superclass, the exn:fail:object exception is raised when the class expression is evaluated.

5.2.3.3 Internal and External Names

Each method declared with public, override, augment, pubment, overment, augride, public-final, override-final, augment-final, inherit, inherit/super, inherit/inner, rename-super, and rename-inner can have separate internal and external names when (internal-id external-id) is used for declaring the method. The internal name is used to access the method directly within the class expression (including within super or inner forms), while the external name is used with send and generic (see Field and Method Access). If a single id is provided for a method declaration, the identifier is used for both the internal and external names.

Method inheritance, overriding, and augmentation are based on external names only. Separate internal and external names are required for rename-super and rename-inner (for historical reasons, mainly).

Each init, init-field, field, or inherit-field variable similarly has an internal and an external name. The internal name is used within the class to access the variable, while the external name is used outside the class when providing initialization arguments (e.g., to instantiate), inheriting a field, or accessing a field externally (e.g., with class-field-accessor). As for methods, when inheriting a field with inherit-field, the external name is matched to an external field name in the superclass, while the internal name is bound in the class expression.

A single identifier can be used as an internal identifier and an external identifier, and it is possible to use the same identifier as internal and external identifiers for different bindings. Furthermore, within a single class, a single name can be used as an external method name, an external field name, and an external initialization argument name. Overall, each internal identifier must be distinct from all other internal identifiers, each external method name must be distinct from all other method names, each external field name must be distinct from all other field names, and each initialization argument name must be distinct from all other initialization argument names.

By default, external names have no lexical scope, which means, for example, that an external method name matches the same syntactic symbol in all uses of send. The define-local-member-name and define-member-name forms introduce scoped external names.

When a class expression is compiled, identifiers used in place of external names must be symbolically distinct (when the corresponding external names are required to be distinct), otherwise a syntax error is reported. When no external name is bound by define-member-name, then the actual external names are guaranteed to be distinct when class expression is evaluated. When any external name is bound by define-member-name, the exn:fail:object exception is raised by class if the actual external names are not distinct.

syntax

(define-local-member-name id ...)

Unless it appears as the top-level definition, binds each id so that, within the scope of the definition, each use of each id as an external name is resolved to a hidden name generated by the define-local-member-name declaration. Thus, methods, fields, and initialization arguments declared with such external-name ids are accessible only in the scope of the define-local-member-name declaration. As a top-level definition, define-local-member-name binds id to its symbolic form.

The binding introduced by define-local-member-name is a syntax binding that can be exported and imported with modules. Each evaluation of a define-local-member-name declaration generates a distinct hidden name (except as a top-level definition). The interface->method-names procedure does not expose hidden names.

Examples:

(define-values (r o)
  (let ()
    (define-local-member-name m)
    (define c% (class object%
                 (define/public (m) 10)
                 (super-new)))
    (define o (new c%))
 
    (values (send o m)
            o)))
> r

10

> (send o m)

send: no such method

  method name: m

  class name: c%

syntax

(define-member-name id key-expr)

Maps a single external name to an external name that is determined by an expression. The value of key-expr must be the result of either a member-name-key expression or a generate-member-key call.

syntax

(member-name-key identifier)

Produces a representation of the external name for id in the environment of the member-name-key expression.

Produces a hidden name, just like the binding for define-local-member-name.

procedure

(member-name-key? v)  boolean?

  v : any/c
Returns #t for values produced by member-name-key and generate-member-key, #f otherwise.

procedure

(member-name-key=? a-key b-key)  boolean?

  a-key : member-name-key?
  b-key : member-name-key?
Produces #t if member-name keys a-key and b-key represent the same external name, #f otherwise.

procedure

(member-name-key-hash-code a-key)  integer?

  a-key : member-name-key?
Produces an integer hash code consistent with member-name-key=? comparisons, analogous to equal-hash-code.

Examples:

(define (make-c% key)
  (define-member-name m key)
  (class object%
    (define/public (m) 10)
    (super-new)))
> (send (new (make-c% (member-name-key m))) m)

10

> (send (new (make-c% (member-name-key p))) m)

send: no such method

  method name: m

  class name: eval:57:0

> (send (new (make-c% (member-name-key p))) p)

10

(define (fresh-c%)
  (let ([key (generate-member-key)])
    (values (make-c% key) key)))
 
(define-values (fc% key) (fresh-c%))

 

> (send (new fc%) m)

send: no such method

  method name: m

  class name: eval:57:0

> (let ()
    (define-member-name p key)
    (send (new fc%) p))

10